Storm exposes a metrics interface to report summary statistics across the full topology. The numbers you see on the UI come from some of these built in metrics, but are reported through the worker heartbeats instead of through the IMetricsConsumer described below.
If you are looking for cluster wide monitoring please see Cluster Metrics.
Metrics have to implement IMetric
which contains just one method, getValueAndReset
– do any remaining work to find the summary value, and reset back to an initial state. For example, the MeanReducer divides the running total by its running count to find the mean, then initializes both values back to zero.
Storm gives you these metric types:
incr()
to increment by one, incrBy(n)
to add/subtract the given number.
reduce()
method. (It accepts Double
, Integer
or Long
values, and maintains the internal average as a Double
.) Despite his reputation, the MeanReducer is actually a pretty nice guy in person.Be aware that even though getValueAndReset
can return an object returning any object makes it very difficult for an IMetricsConsumer
to know how to translate it into something usable. Also note that because it is sent to the IMetricsConsumer
as a part of a tuple the values returned need to be able to be serialized by your topology.
You can listen and handle the topology metrics via registering Metrics Consumer to your topology.
To register metrics consumer to your topology, add to your topology’s configuration like:
conf.registerMetricsConsumer(org.apache.storm.metric.LoggingMetricsConsumer.class, 1);
You can refer Config#registerMetricsConsumer and overloaded methods from javadoc.
Otherwise edit the storm.yaml config file:
topology.metrics.consumer.register:
- class: "org.apache.storm.metric.LoggingMetricsConsumer"
parallelism.hint: 1
- class: "org.apache.storm.metric.HttpForwardingMetricsConsumer"
parallelism.hint: 1
argument: "http://example.com:8080/metrics/my-topology/"
Storm adds a MetricsConsumerBolt to your topolology for each class in the topology.metrics.consumer.register
list. Each MetricsConsumerBolt subscribes to receive metrics from all tasks in the topology. The parallelism for each Bolt is set to parallelism.hint
and component id
for that Bolt is set to __metrics_<metrics consumer class name>
. If you register the same class name more than once, postfix #<sequence number>
is appended to component id.
Storm provides some built-in metrics consumers for you to try out to see which metrics are provided in your topology.
LoggingMetricsConsumer
– listens for all metrics and dumps them to log file with TSV (Tab Separated Values).HttpForwardingMetricsConsumer
– listens for all metrics and POSTs them serialized to a configured URL via HTTP. Storm also provides HttpForwardingMetricsServer
as abstract class so you can extend this class and run as a HTTP server, and handle metrics sent by HttpForwardingMetricsConsumer.Also, Storm exposes the interface IMetricsConsumer
for implementing Metrics Consumer so you can create custom metrics consumers and attach to their topologies, or use other great implementation of Metrics Consumers provided by Storm community. Some of examples are versign/storm-graphite, and storm-metrics-statsd.
When you implement your own metrics consumer, argument
is passed to Object when IMetricsConsumer#prepare is called, so you need to infer the Java type of configured value on yaml, and do explicit type casting.
Please keep in mind that MetricsConsumerBolt is just a kind of Bolt, so whole throughput of the topology will go down when registered metrics consumers cannot keep up handling incoming metrics, so you may want to take care of those Bolts like normal Bolts. One of idea to avoid this is making your implementation of Metrics Consumer as non-blocking
fashion.
You can measure your own metric by registering IMetric
to Metric Registry.
Suppose we would like to measure execution count of Bolt#execute. Let’s start with defining metric instance. CountMetric seems to fit our use case.
private transient CountMetric countMetric;
Notice we define it as transient. IMertic is not Serializable so we defined as transient to avoid any serialization issues.
Next, let’s initialize and register the metric instance.
@Override
public void prepare(Map conf, TopologyContext context, OutputCollector collector) {
// other initialization here.
countMetric = new CountMetric();
context.registerMetric("execute_count", countMetric, 60);
}
The meaning of first and second parameters are straightforward, metric name and instance of IMetric. Third parameter of TopologyContext#registerMetric is the period (seconds) to publish and reset the metric.
Last, let’s increment the value when Bolt.execute() is executed.
public void execute(Tuple input) {
countMetric.incr();
// handle tuple here.
}
Note that sample rate for topology metrics is not applied to custom metrics since we’re calling incr() ourselves.
Done! countMetric.getValueAndReset()
is called every 60 seconds as we registered as period, and pair of (“execute_count”, value) will be pushed to MetricsConsumer.
You can register your own worker level metrics by adding them to Config.WORKER_METRICS
for all workers in cluster, or Config.TOPOLOGY_WORKER_METRICS
for all workers in specific topology.
For example, we can add worker.metrics
to storm.yaml in cluster,
worker.metrics:
metricA: "aaa.bbb.ccc.ddd.MetricA"
metricB: "aaa.bbb.ccc.ddd.MetricB"
...
or put Map<String, String>
(metric name, metric class name) with key Config.TOPOLOGY_WORKER_METRICS
to config map.
There are some restrictions for worker level metric instances:
A) Metrics for worker level should be kind of gauge since it is initialized and registered from SystemBolt and not exposed to user tasks.
B) Metrics will be initialized with default constructor, and no injection for configuration or object will be performed.
C) Bucket size (seconds) for metrics is fixed to Config.TOPOLOGY_BUILTIN_METRICS_BUCKET_SIZE_SECS
.
The builtin metrics instrument Storm itself.
BuiltinMetricsUtil.java sets up data structures for the built-in metrics, and facade methods that the other framework components can use to update them. The metrics themselves are calculated in the calling code – see for example ackSpoutMsg
.
The rate at which built in metrics are reported is configurable through the topology.builtin.metrics.bucket.size.secs
config. If you set this too low it can overload the consumers,
so please use caution when modifying it.
There are several different metrics related to counting what a bolt or spout does to a tuple. These include things like emitting, transferring, acking, and failing of tuples.
In general all of these tuple count metrics are randomly sub-sampled unless otherwise stated. This means that the counts you see both on the UI and from the built in metrics are not necessarily exact. In fact by default we sample only 5% of the events and estimate the total number of events from that. The sampling percentage is configurable per topology through the topology.stats.sample.rate
config. Setting it to 1.0 will make the counts exact, but be aware that the more events we sample the slower your topology will run (as the metrics are counted in the same code path as tuples are processed). This is why we have a 5% sample rate as the default.
The tuple counting metric names contain "${stream_name}"
or "${upstream_component}:${stream_name}"
. The former is used for all spout metrics and for outgoing bolt metrics (__emit-count
and __transfer-count
). The latter is used for bolt metrics that deal with incoming tuples.
So for a word count topology the count bolt might show something like the following for the __ack-count
metric
"__ack-count-split:default": 80080
But the spout instead would show something like the following for the __ack-count
metric.
"__ack-count-default": 12500
__ack-count
For bolts it is the number of incoming tuples that had the ack
method called on them. For spouts it is the number of tuples trees that were fully acked. See Guaranteeing Message Processing for more information about what a tuple tree is. If acking is disabled this metric is still reported, but it is not really meaningful.
__fail-count
For bolts this is the number of incoming tuples that had the fail
method called on them. For spouts this is the number of tuple trees that failed. Tuple trees may fail from timing out or because a bolt called fail on it. The two are not separated out by this metric.
__emit-count
This is the total number of times the emit
method was called to send a tuple. This is the same for both bolts and spouts.
__transfer-count
This is the total number of tuples transferred to a downstream bolt/spout for processing. This number will not always match __emit_count
. If nothing is registered to receive a tuple down stream the number will be 0 even if tuples were emitted. Similarly if there are multiple down stream consumers it may be a multiple of the number emitted. The grouping also can play a role if it sends the tuple to multiple instances of a single bolt down stream.
__execute-count
This count metric is bolt specific. It counts the number of times that a bolt’s execute
method was called.
Similar to the tuple counting metrics storm also collects average latency metrics for bolts and spouts. These follow the same structure as the bolt/spout maps and are sub-sampled in the same way as well. In all cases the latency is measured in milliseconds.
__complete-latency
The complete latency is just for spouts. It is the average amount of time it took for ack
or fail
to be called for a tuple after it was emitted. If acking is disabled this metric is likely to be blank or 0 for all values, and should be ignored.
__execute-latency
This is just for bolts. It is the average amount of time that the bolt spent in the call to the execute
method. The higher this gets, the lower the throughput of tuples per bolt instance.
__process-latency
This is also just for bolts. It is the average amount of time between when execute
was called to start processing a tuple, to when it was acked or failed by the bolt. If your bolt is a very simple bolt and the processing is synchronous then __process-latency
and __execute-latency
should be very close to one another, with process latency being slightly smaller. If you are doing a join or have asynchronous processing then it may take a while for a tuple to be acked so the process latency would be higher than the execute latency.
__skipped-max-spout-ms
This metric records how much time a spout was idle because more tuples than topology.max.spout.pending
were still outstanding. This is the total time in milliseconds, not the average amount of time and is not sub-sampled.
__skipped-backpressure-ms
This metric records how much time a spout was idle because back-pressure indicated that downstream queues in the topology were too full. This is the total time in milliseconds, not the average amount of time and is not sub-sampled. This is similar to skipped-throttle-ms in Storm 1.x.
__backpressure-last-overflow-count
This metric indicates the overflow count last time BP status was sent, with a minimum value of 1 if a task has backpressure on.
skipped-inactive-ms
This metric records how much time a spout was idle because the topology was deactivated. This is the total time in milliseconds, not the average amount of time and is not sub-sampled.
Storm also collects error reporting metrics for bolts and spouts.
__reported-error-count
This metric records how many errors were reported by a spout/bolt. It is the total number of times the reportError
method was called.
Each bolt or spout instance in a topology has a receive queue. Each worker also has a worker transfer queue for sending messages to other workers. All of these have metrics that are reported.
The receive queue metrics are reported under the receive_queue
name. The metrics for the queue that sends messages to other workers is under the worker-transfer-queue
metric name for the system bolt (__system
).
These queues report the following metrics:
{
"arrival_rate_secs": 1229.1195171893523,
"overflow": 0,
"sojourn_time_ms": 2.440771591407277,
"capacity": 1024,
"population": 19,
"pct_full": "0.018".
"insert_failures": "0",
"dropped_messages": "0"
}
arrival_rate_secs
is an estimation of the number of tuples that are inserted into the queue in one second, although it is actually the dequeue rate.
The sojourn_time_ms
is calculated from the arrival rate and is an estimate of how many milliseconds each tuple sits in the queue before it is processed.
The queue has a set maximum number of entries. If the regular queue fills up an overflow queue takes over. The number of tuples stored in this overflow section are represented by the overflow
metric. Note that an overflow queue is only used for executors to receive tuples from remote workers. It doesn’t apply to intra-worker tuple transfer.
capacity
is the maximum number of entries in the queue. population
is the number of entries currently filled in the queue. ‘pct_full’ tracks the percentage of capacity in use.
‘insert_failures’ tracks the number of failures inserting into the queue. ‘dropped_messages’ tracks messages dropped due to the overflow queue being full.
The System Bolt __system
provides lots of metrics for different worker wide things. The one metric not described here is the __transfer
queue metric, because it fits with the other disruptor metrics described above.
Be aware that the __system
bolt is an actual bolt so regular bolt metrics described above also will be reported for it.
__recv-iconnection
reports stats for the netty server on the worker. This is what gets messages from other workers. It is of the form
{
"dequeuedMessages": 0,
"enqueued": {
"/127.0.0.1:49952": 389951
}
}
dequeuedMessages
is a throwback to older code where there was an internal queue between the server and the bolts/spouts. That is no longer the case and the value can be ignored.
enqueued
is a map between the address of the remote worker and the number of tuples that were sent from it to this worker.
The __send-iconnection
metrics report information about all of the clients for this worker. They are named __send-iconnection-METRIC_TYPE-HOST:PORT for a given Client that is
connected to a worker with the given host/port. These metrics can be disabled by setting topology.enable.send.iconnection.metrics to false.
The metric types reported for each client are:
reconnects
the number of reconnections that have happened.pending
the number of messages that have not been sent. (This corresponds to messages, not tuples)sent
the number of messages that have been sent. (This is messages not tuples)lostOnSend
. This is the number of messages that were lost because of connection issues. (This is messages not tuples).JVM memory usage is reported through memory.non-heap
for off heap memory, memory.heap
for on heap memory and memory.total
for combined values. These values come from the MemoryUsage mxbean. Each of the metrics are reported as a map with the following keys, and values returned by the corresponding java code.
Key | Corresponding Code |
---|---|
max |
memUsage.getMax() |
committed |
memUsage.getCommitted() |
init |
memUsage.getInit() |
used |
memUsage.getUsed() |
usage |
Ratio.of(memUsage.getUsed(), memUsage.getMax()) |
The exact GC metric name depends on the garbage collector that your worker uses. The data is all collected from ManagementFactory.getGarbageCollectorMXBeans()
and the name of the metrics is "GC"
followed by the name of the returned bean with white space removed. The reported metrics are just
count
the number of gc events that happened andtime
the total number of milliseconds that were spent doing gc.Please refer to the JVM documentation for more details.
threads
providing the number of threads, daemon threads, blocked and deadlocked threads.uptimeSecs
reports the number of seconds the worker has been up fornewWorkerEvent
is 1 when a worker is first started and 0 all other times. This can be used to tell when a worker has crashed and is restarted.startTimeSecs
is when the worker started in seconds since the epochdoHeartbeat-calls
is a meter that indicates the rate the worker is performing heartbeats.